Abstract
AbstractMarine algae are key sources of the biogenic sulfur compound dimethylsulphoniopropionate (DMSP), a vital component of the marine sulfur cycle. Autotrophic ecosystem engineers such as red coralline algae support highly diverse and biogeochemically active ecosystems and are known to be high DMSP producers, but their importance in the global marine sulfur cycle has not yet been appreciated. Using a global sampling approach, we show that red coralline algae are a globally significant pool of DMSP in the oceans, estimated to be ~110 × 1012 moles worldwide during the summer months. Latitude was a major driver of observed regional‐scale variations, with peaks in polar and tropical climate regimes, reflecting the varied cellular functions for DMSP (e.g., as a cryoprotectant and antioxidant). A temperate coralline algal bed was investigated in more detail to also identify local‐scale temporal variations. Here, water column DMSP was driven by water temperature, and to a lesser extent, cloud cover; two factors which are also vital in controlling coralline algal growth. This study demonstrates that coralline algae harbor a large pool of dimethylated sulfur, thereby playing a significant role in both the sulfur and carbon marine biogeochemical cycles. However, coralline algal habitats are severely threatened by projected climate change; a loss of this habitat may thus detrimentally impact oceanic sulfur and carbon biogeochemical cycling.
Highlights
Dimethylsulphoniopropionate (DMSP) and its breakdown product DMS have been linked to global climate regulation via the formation of atmospheric aerosols [Charlson et al, 1987]
Using a global sampling approach, we show that red coralline algae are a globally significant pool of DMSP in the oceans, estimated to be ~110 × 1012 moles worldwide during the summer months
Water column DMSP was driven by water temperature, and to a lesser extent, cloud cover; two factors which are vital in controlling coralline algal growth
Summary
Dimethylsulphoniopropionate (DMSP) and its breakdown product DMS (collectively DMS/P) have been linked to global climate regulation via the formation of atmospheric aerosols [Charlson et al, 1987]. Spatiotemporal patterns appear to reflect the proposed cellular functions of DMSP. In tropical coral reef ecosystems, peaks in coral and water column DMS/P are observed in the summer months [Broadbent and Jones, 2006; Jones et al, 2007], supporting the antioxidant function hypothesis [Sunda et al, 2002]. Peak concentrations in intracellular DMSP in the invasive macroalga Codium fragile are observed in late winter, supporting the proposed cryoprotective function [Lyons et al, 2007, 2010]. Regional-scale spatiotemporal variations in benthic ecosystem DMS/P are yet to be determined
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